Complex dimension

In physics, Larmor precession (named after Joseph Larmor) is the precession of the magnetic moments of electrons, muons, all leptons with magnetic moments which are quantum effects of particle spin, atomic nuclei, and atoms about an external magnetic field. The magnetic field exerts a torque on the magnetic moment,

${\displaystyle {\vec {\Gamma }}={\vec {\mu }}\times {\vec {B}}=\gamma {\vec {J}}\times {\vec {B}}}$

where ${\displaystyle {\vec {\Gamma }}}$ is the torque, ${\displaystyle {\vec {\mu }}}$ is the magnetic dipole moment, ${\displaystyle {\vec {J}}}$ is the angular momentum vector, ${\displaystyle {\vec {B}}}$ is the external magnetic field, ${\displaystyle \times }$ symbolizes the cross product, and ${\displaystyle \ \gamma }$ is the gyromagnetic ratio which gives the proportionality constant between the magnetic moment and the angular momentum.

Larmor frequency

The angular momentum vector ${\displaystyle {\vec {J}}}$ precesses about the external field axis with an angular frequency known as the Larmor frequency,

${\displaystyle \omega =-\gamma B}$

where ${\displaystyle \omega }$ is the angular frequency,^[1] ${\displaystyle \gamma ={\frac {-eg}{2m}}}$ is the gyromagnetic ratio, and ${\displaystyle B}$ is the magnitude of the magnetic field^[2] and ${\displaystyle g}$ is the g-factor (normally 1, except in quantum physics).

Simplified, this becomes:

${\displaystyle \omega ={\frac {egB}{2m}}}$

where ${\displaystyle \omega }$ is the Larmor frequency, m is mass, e is charge, and B is applied field. For a given nucleus, the g-factor includes the effects of the spin of the nucleons as well as their orbital angular momentum and the coupling between the two. Because the nucleus is so complicated, g factors are very difficult to calculate, but they have been measured to high precision for most nuclei. Each nuclear isotope has a unique Larmor frequency for NMR spectroscopy, which is tabulated here.

Including Thomas precession

The above equation is the one that is used in most applications. However, a full treatment must include the effects of Thomas precession, yielding the equation (in CGS units):

${\displaystyle \omega _{s}={\frac {geB}{2mc}}+(1-\gamma ){\frac {eB}{mc\gamma }}}$

where ${\displaystyle \gamma }$ is the relativistic gamma factor (not to be confused with the gyromagnetic ratio above). Notably, for the electron g is very close to 2 (2.002..), so if one sets g=2, one arrives at

${\displaystyle \omega _{s(g=2)}={\frac {eB}{mc\gamma }}}$

Bargmann–Michel–Telegdi equation

The spin precession of an electron in an external electromagnetic field is described by the Bargmann–Michel–Telegdi (BMT) equation ^[3]

${\displaystyle {\frac {da^{\tau }}{ds}}={\frac {e}{m}}u^{\tau }u_{\sigma }F^{\sigma \lambda }a_{\lambda }+2\mu (F^{\tau \lambda }-u^{\tau }u_{\sigma }F^{\sigma \lambda })a_{\lambda },}$

where ${\displaystyle a^{\tau }}$, ${\displaystyle e}$, ${\displaystyle m}$, and ${\displaystyle \mu }$ are polarization four-vector, charge, mass, and magnetic moment, ${\displaystyle u^{\tau }}$ is four-velocity of electron, ${\displaystyle a^{\tau }a_{\tau }=-u^{\tau }u_{\tau }=-1}$, ${\displaystyle u^{\tau }a_{\tau }=0}$, and ${\displaystyle F^{\tau \sigma }}$ is electromagnetic field-strength tensor. Using equations of motion,

${\displaystyle m{\frac {du^{\tau }}{ds}}=eF^{\tau \sigma }u_{\sigma },}$

one can rewrite the first term in the right side of the BMT equation as ${\displaystyle (-u^{\tau }w^{\lambda }+u^{\lambda }w^{\tau })a_{\lambda }}$, where ${\displaystyle w^{\tau }=du^{\tau }/ds}$ is four-acceleration. This term describes Fermi–Walker transport and leads to Thomas precession. The second term is associated with Larmor precession.

When electromagnetic fields are uniform in space or when gradient forces like ${\displaystyle \nabla ({\boldsymbol {\mu }}\cdot {\boldsymbol {B}})}$ can be neglected, the particle's translational motion is described by

${\displaystyle {du^{\alpha } \over d\tau }={e \over m}F^{\alpha \beta }u_{\beta }\;.}$

The BMT equation is then written as ^[4]

${\displaystyle {\;\,dS^{\alpha } \over d\tau }={e \over m}{\bigg [}{g \over 2}F^{\alpha \beta }S_{\beta }+\left({g \over 2}-1\right)u^{\alpha }\left(S_{\lambda }F^{\lambda \mu }U_{\mu }\right){\bigg ]}\;,}$

The Beam-Optical version of the Thomas-BMT, from the Quantum Theory of Charged-Particle Beam Optics, applicable in accelerator optics ^{[5] [6]}

Applications

A 1935 paper published by Lev Landau and Evgeny Lifshitz predicted the existence of ferromagnetic resonance of the Larmor precession, which was independently verified in experiments by J. H. E. Griffiths (UK) and E. K. Zavoiskij (USSR) in 1946.

Larmor precession is important in nuclear magnetic resonance, electron paramagnetic resonance and muon spin resonance. It is also important for the alignment of cosmic dust grains, which is a cause of the polarization of starlight.

To calculate the spin of a particle in a magnetic field, one must also take into account Thomas precession.

Precession direction

The precession direction is determined by the chirality of the particle.

See also

• Rabi cycle
• LARMOR neutron microscope

Notes

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External links

• Georgia State University HyperPhysics page on Larmor Frequency
• Larmor Frequency Calculator